Gallium Nitride on Silicon Epitaxial Wafers
GaN on Silicon Epi-Wafer Benefits and Typical Applications
GaN on Si have high-uniformity and good repeatability with low leakage current with excellent 2DEG transport properties. GaN on Si are great for power HEMTs and low cost CMOS process. And the wafers are suitable for power diodes.
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What are Gallium Nitride on Silicon Epitaxial Wafers Applications?
Gallium Nitride (GaN) on Silicon Epitaxial Wafers combines the wide bandgap properties of GaN with the cost-effectiveness of silicon, enabling various high-performance applications. Here are some of the primary applications:
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Power Electronics: GaN on silicon wafers is highly suitable for high-voltage and high-power devices, like power converters, inverters, and power management integrated circuits (ICs). GaN's high breakdown voltage, fast switching speeds, and efficiency at high frequencies make it ideal for electric vehicles, data centers, renewable energy systems, and consumer electronics.
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RF and Microwave Devices: Due to its high electron mobility and saturation velocity, GaN is valuable in high-frequency applications. GaN-on-Silicon wafers are widely used in radio frequency (RF) amplifiers, particularly in 5G base stations, satellite communications, and radar systems.
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LEDs and Solid-State Lighting: GaN is foundational in LED technology due to its blue and UV light emission capabilities. GaN on silicon offers a more economical solution for producing LEDs, making it useful for displays, automotive lighting, and other solid-state lighting applications.
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Optoelectronics: GaN-on-Si wafers are also useful for various optoelectronic devices, such as laser diodes, photodetectors, and optical sensors. These are often used in data storage, optical communication, and imaging.
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Sensors: GaN on Silicon can also be used in harsh-environment sensors due to its thermal and chemical stability, especially where high temperatures or corrosive conditions are involved, such as in industrial, automotive, and aerospace applications.
By integrating GaN with silicon, manufacturers achieve a blend of performance benefits from GaN while leveraging the silicon infrastructure and cost advantages, particularly as GaN-on-Silicon technology continues to advance.
Gallium Nitride/ Silicon Epiwafers
Gallium Nitride (GaN) on Silicon (Si) substrates applications include next-generation ultra-thin-film semiconductors. Gallium Nitride EP wafers on SiC substrates Application GaN epitaxial wafers can be used as a substrate for III-V nitride epitaxial growth via MBE, MOCVD, and CVD. GaN epitaxial wafers are composite multi-layer (Al, In, Ga)n formations developed through metal-integrated chemical substance vapour deposition (MOCVD) processes, on either Silicon or Silicon Carbide (SiC) wafers.
| Features Overview | Typical Applications |
|---|---|
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Wafer Size and Epi-Structure
| GaN cap layer | Specification | Values |
|---|---|---|
| AlGaN or InAlN Barrier | Diameter | 100mm / 150mm |
| GaN Channel | Epi Thickness | 2-3 Micron |
| (Al) Gan buffers (RF buffer) | Bowing | <= 30 micron |
| HR-Si (111) Substrate | Sheet resistance | <= 350 ohm-cm |
| RF Loss | <=0.2dB/mm@6GHz |
| Item | Criteria | Typical | Condition |
|---|---|---|---|
| Crystal Quality of GaN Buffer (arcsec) | |||
| XRC FWHM(002) | <=800 | 700 | XRD |
| XRC FWHM(102) | <=1200 | 900 | XRD |
| 2DEG Transport Properties | |||
| Mobility | >=1800 | 1900 | Hall |
| Concentration | >=9E12 | 1E13 | Hall |
| Rsh | <=350 | 300 | Hall |
| Wafer Profile and Surface Characteristics | |||
| Wafer Bow | <=30mm | <=20 | PL mapping |
| Total Defect | |||
| Edge Crach | <=3mm | 1mm | |
| Scratch | No | No | |
| RMS@5x5 μm2 | <=0.5nm | 0.3nm | AFM |
Typical Characteristics Datasheet
| Al% Uniformity for AlGaN | Wafer bowing mapping | Sheet Resistance Mapping |
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Gallium Nitride/NPSS Epiwafers
Gallium Nitride operates at far higher voltages, frequencies, and temperatures than traditional semiconductor materials like silicon, enabling higher efficiency, smaller size, lighter weight, higher speed, and lower cost final products. The larger diameter of GaNs engineered substrate wafers allows for a larger number of viable GaN devices to be produced per wafer, thus leading to lower cost manufacturing. Since the GaN devices are using a standard silicon substrate, no cost savings are available when compared with Power MOSFET manufacturing at similar diameters as the substrate material.
Features overview include:
- High uniformity and good repeatability
- Based on NPSS or AlN template
Wafer Size and Epi-Structure
| Mesa depth 450nm | ||
|---|---|---|
| p++ GaN | Parameters | Specification |
| p AlGaN | Wafer Size | 50.8mm |
| EBL | Total Thickness | 4.6~4.8um |
| MQWs | XRC of AlN Template | (002):≤200 arcsec,(102):≤300 arcsec |
| n AlGaN | Concentration of n-AlGaN | ≥1 E19/cm3 |
| Transition Layer | ||
| AlN on NPSS |
Optical Characteristics
| Parameters | Symbol | Condition | Unit | Min | Typ | Max | |
|---|---|---|---|---|---|---|---|
| Output power | Po | 2020@100 Ma | mW | - | >=10 | ||
| Wavelength | Wp | nm | 270 | 275 | 280 | ||
| FWHM of PL peak | Wh | nm | - | 12 | 13 | ||
| Forward Voltage | Vf | V | - | 6 | 6.5 |
Surface Defects
| No. | Parameters | Criteria | Typical Characteristics Datasheet |
|---|---|---|---|
| 1. | Edge Exclusion | <=3mm |
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| 2. | Crack | <=50 | |
| 3. | Haze | None | |
| 4. | Hillock | <=100 ea@1mm2, 50 x optical microscope | |
| 5. | Scratch | None | |
| 6. | Contamination | None | |
| 7. | Bowing | <=150 micron |
GaN Epi Wafers
Below are just some of Gallium Nitride Epitaxial Wafers that we have in stock. Please select the item(s) and quantity for an immediate quote, or send us your specs for a custom quote.
GaN-on-Sapphire Wafer Series Prime grade |
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| Diameter | Orient. | Substrate Thickness | Surface Finish | GaN Template Thickness | Conduction Type | Dopant | Quantity | |||||
| 2 | <0001> | 430+/-25um | SSP,Flat Sapphire | 800nm | N-type | Un-doped | </=25 | |||||
| 2 | <0001> | 430+/-25um | DSP,Flat Sapphire | 800nm | N-type | Un-doped | </=25 | |||||
| 2 | <0001> | 430+/-25um | SSP,Flat Sapphire | 5.0um | N-type | Un-doped | </=25 | |||||
| 2 | <0001> | 430+/-25um | SSP,Flat Sapphire | 5.0um | N-type | Si-doped | </=25 | |||||
| 2 | <0001> | 430+/-25um | DSP,Flat Sapphire | 5.0um | N-type | Si-doped | </=25 | |||||
| 2 | <0001> | 430+/-25um | SSP,PSS Substrate | 5.0um | N-type | Un-doped | </=25 | |||||
| 2 | <0001> | 430+/-25um | SSP,PSS Substrate | 4.0um | N-type | Si-doped | </=25 | |||||
| 2 | <0001> | 430+/-25um | SSP,PSS Substrate | 6.0um | N-type | Si-doped | </=25 | |||||
| 2 | <0001> | 430+/-25um | Single Side Polished | 4~5um | Semi Insulating | Fe-doped | </=25 | |||||
| 2 | <0001> | 430+/-25um | Single Side Polished | P 0.5/UID 2.0um | P-type | Mg-doped | </=25 | |||||
| 2 | <0001> | 430+/-25um | Single Side Polished | 5.0um | P-type | Mg-doped | </=25 | |||||
| 2 | <0001> | 430+/-25um | Double Side Polished | 5.0um | P-type | Mg-doped | </=25 | |||||
| / | ||||||||||||
| 4 | <0001> | 650+/-25um | Single Side Polished | 600nm | N-type | Un-doped | </=25 | |||||
| 4 | <0001> | 650+/-25um | Single Side Polished | 5.0um | N-type | Un-doped | </=25 | |||||
| 4 | <0001> | 650+/-25um | Double Side Polished | 5.0um | N-type | Un-doped | </=25 | |||||
| 4 | <0001> | 650+/-25um | Single Side Polished | 5.0um | N-type | Si-doped | </=25 | |||||
| 4 | <0001> | 650+/-25um | Double Side Polished | 5.0um | N-type | Si-doped | </=25 | |||||
| 4 | <0001> | 650+/-25um | SSP,PSS Substrate | 5.0um | N-type | Si-doped | </=25 | |||||
| / | ||||||||||||
| 6 | <0001> | 1300+/-25um | Single Side Polished | 3.0um | N-type | Un-doped | </=25 | |||||
| 6 | <0001> | 1000+/-25um | Single Side Polished | 5.0um | N-type | Un-doped | </=25 | |||||
| 6 | <0001> | 1000+/-25um | Single Side Polished | 5.0um | N-type | Si-doped | </=25 | |||||
| 6 | <0001> | 1000+/-25um | Double Side Polished | 5.0um | N-type | Si-doped | </=25 | |||||
| 2~6 | <0001> | 430~1300+/-25um | SSP / DSP | LED epi structure 4~6um | LED Epi Wafer | Blue/Green | </=25 | |||||
| 2 | <0001> | 400+/-30um | SSP / DSP | GaN on GaN Substrate | N/S.I | N/S.I | </=25 | |||||
GaN-on-Silicon Wafer Series Prime grade |
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| Diameter | Orient. | Substrate Thickness | Surface Finish | GaN Template Thickness | Conduction Type | Dopant | Quantity | |||||
| 2 | <111> | 1000+/-25um | P/E | 100~5000nm | N-type | Un-doped | </=25 | |||||
| 4 | <111> | 525~1000+/-25um | P/E | 100~5000nm | N-type | Un-doped | </=25 | |||||
| 6 | <111> | 675~1000+/-25um | P/E | 100~5000nm | N-type | Un-doped | </=25 | |||||
| 8 | <111> | 725~1000+/-25um | P/E | 100~5000nm | N-type | Un-doped | </=25 | |||||
| 2~8 | <111> | 500~1000+/-25um | P/E | HEMT Structure GaN | N/S.I-type | S.I-doped | </=25 | |||||
| 4~6 | <111> | 500~1000+/-25um | P/E | Blue/Green LED GaN on Si | N/P-type | N/P-doped | </=25 | |||||
| 2~8 | <111> | 500~1000+/-25um | P/E | 100~500nm AlN | S.I-type | Un-doped | </=25 | |||||
GaN-on-Silicon Carbide (SiC) Wafer Series Prime grade |
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| Diameter | Orient. | Substrate Thickness | Surface Finish | GaN Template Thickness | Conduction Type | Dopant | Quantity | |||||
| 2 | <0001> | 350/500+/-25um | P/P | 100~3000nm | N/S.I-type | Si/Fe | </=25 | |||||
| 4 | <0001> | 350/500+/-25um | P/P | 100~3000nm | N/S.I-type | Si/Fe | </=25 | |||||
| 6 | <0001> | 350/500+/-25um | P/P | 100~3000nm | N/S.I-type | Si/Fe | </=25 | |||||
Bulk GaN Wafer Series Prime grade |
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| Diameter | Orient. | Substrate Thickness | Surface Finish | GaN Template Thickness | Conduction Type | Dopant | Quantity | |||||
| 2 | <0001> | 400+/-30um | SSP / DSP | Bulk GaN Wafer | N/S.I | N/S.I | </=25 | |||||
| 4 | <0001> | 600+/-30um | SSP / DSP | Bulk GaN Wafer | N/S.I | N/S.I | </=25 | |||||
| 2 | <0001> | 400+/-30um | SSP / DSP | GaN Epi on GaN Substrate | N/S.I | N/S.I | </=25A38:M51A34:M51A30A7:M51 | |||||